DE1018995B - Power converter - Google Patents

Description

Current transformer Current transformer for higher series voltages with smaller Performance and high accuracy. as is generally known, a relatively large one Overcurrent figure, while current transformers have a higher power and lower Accuracy is a small overcurrent digit. The overcurrent digit "n" applies as a measure of the overcurrent behavior of a current transformer and is a first approximation by the ratio of limit saturation to nominal induction of the core material used fixed at a certain burden.

All measuring cores generally have a relatively small power Required with high measurement accuracy, so that with a large amount of material for the core only a low nominal saturation is achieved. So the overcurrent figure is very large, o1 -) - probably in these cases with consideration of the endangerment of the secondary connected, often sensitive measuring devices should be small. With relay cores as burdens, the circumstances are exactly the opposite. The low accuracy of the Connection of relays to current transformers does not require excessive use of the S.troinwandler core cross-section, so that in connection with the relatively large power only a small upper current figure is given. However, when connecting relays a large overcurrent figure is desirable.

Particularly unfavorable conditions arise during use of rod current transformers, because of the cost of materials, especially with small nominal currents is particularly large in its core and therefore often extremely high with a small measuring power Overcurrent factor must be accepted. To the connected sensitive It is necessary to protect measuring instruments from damage in the event of severe short circuits in the network to limit the current in the secondary measuring circuit. For the limitation there there are known different possibilities. Through the use of nickel iron alloys Instead of normal dynamo sheets, the overcurrent factor can be reduced, as the saturation limit of the nickel iron alloys commonly used in current transformers, for example three times lower than the usual silicon iron. Since the magnetic The conductivity of the nickel iron alloys is better, with the same measuring performance the core cross-section is reduced and thus again a reduction in the overcurrent, can be achieved. However, these measures are due to high prices for the core materials very expensive, so that not always a particularly economical solution can be spoken.

Furthermore, so-called current switches have already been proposed, as a choke coil with nickel egg sinker parallel to the useful load of a converter should be switched with a large overcurrent figure. These chokes are designed so that they only consume an itrom of a few mA when the converter is in nominal operation and so that it does not significantly affect the actual measurement. When occurring. one In the event of a short circuit in the network, the secondary current of the converter increases with the primary current strong. The amount on the secondary terminals of the N @ randler also increases Burden voltage. The resulting increase in induction in the current switch, their The core is already saturated at around 6000 Gauss, the choke takes its almost completely high inductance that was present during nominal operation. But that can get through the short-circuit conditional high secondary current flow through the choke, so that the: connected Instruments and meters are protected against power failure. These power lines are also not cheap because of their relatively large nickel iron core. Also is In many cases, the use of these current switches is only possible if a calibration is carried out this throttle can be carried out with the associated converter.

With a current transformer, especially with a rod current transformer Main and auxiliary core of the same primary electrical flow, whose the burden feeding secondary windings are connected in parallel in the same direction, all these disadvantages are avoided according to the invention in that the auxiliary core is taken into account of the core material with regard to its effective cross-section and the number of turns its Selsun: därwick is measured in such a way that already in a manner known per se a relatively high core induction in the initial area of its Nenn.stro@mbeTeiches is present, so that the main and auxiliary kernels have a generative effect, and that the auxiliary kernel when the rated current range is exceeded, it saturates, so that from there acts as a consumer. Current transformers are with auxiliary cores and connected in parallel Secondary windings known. However, all of these art circuits are for exaltation the 14 Measuring accuracy. So you don't pursue that through the invention Desired purpose of increasing the excessive excess flow rate without additional switching elements.

The sel: and därwicl: lungen of both nuclei are connected in parallel and feed the burden circle together. Thereby the number of turns of both coils for example chosen so that there is a secondary measuring core for the actual measuring core Nominal current strength of 4A and for the auxiliary core a current strength of 1 A results, at Connection of measuring devices: n to the secondary terminals flows into it during nominal operation Secondary: rom of 5 A in the load circuit. The cross-section of the auxiliary core is dimensioned so that on the one hand already at low excitement there is a relatively fast induction and thereby, especially with la-in_ ° n primary.trö, m, eii, an improvement of the error l: tirve occurs and in others when the rated current range of the auxiliary core is exceeded is almost completely saturated, so that the secondary current is now over the parallel-connected winding of the saturated auxiliary voltage flows and thus the actual Biird, nlcreis effectively relieved.

An embodiment of the invention is shown schematically in the drawing shown.

1 shows the existing NTeßl: ern 1 with the primary winding 2 and the secondary winding 3. In addition, the auxiliary core 4 with its secondary winding 5 is applied to the common primary winding 2. Both secondary windings are then connected in parallel to terminals 1a and I of burden 6. The arrangement according to the invention then has the following mode of operation: With small currents, ie in the nominal current range, the measuring and auxiliary core work in parallel and supply the load circuit with a current that - in the case of the example above - is proportional to the nominal current of 4 or 1 A. Both cores therefore act as a generator. Because of its small cross-section, the small auxiliary core is operated with a relatively high induction even at a low AW number. As a result of the considerably higher induction of the auxiliary core compared to the measuring core, even with small currents, the former has a smaller measurement error than the measuring core, so that, especially with small excitation currents, an improvement in the error curve is achieved compared to a single core. This applies in particular to the errors at 0.1 - In and 0.2 - 7 ". As the primary current rises, the induction in the auxiliary core increases in such a way that, towards the end of the phase, saturation phenomena become noticeable, which lower the resistance of the If the primary current continues to rise after the auxiliary core is saturated, the auxiliary core winding takes up current from the secondary winding of the: Vleßkernes, which is directed opposite to the current supplied by the auxiliary core and then magnetizes in the same way as the primary current the auxiliary core acts, whereby the saturation in the auxiliary core is accelerated even more.

With this arrangement it is possible with less effort each Overcurrent figure between approx. = 1.5 and the value that is reached at the normal design of the current transformer with only one core. The overtime number can thus by -a appropriately sized cross-section of the auxiliary core change downwards at will within wide limits. There is performance and accuracy of the actual measuring core for the overcurrent figure of the overall arrangement only from subordinate Meaning.

Another advantage of this' measuring arrangement results for transducers with small primary currents, where the secondary number of turns is often so low is that it is very difficult to carry out an error adjustment. At a gear ratio of, for example, 100i5 A, the secondary number of turns is only without correction 20 turns. The correction of a single turn therefore already means a change in error from 51 / o. which in most cases must be viewed as much too coarse. at Using the measures according to the invention, there would be about 100 secondary turns on the auxiliary core to be raised. By changing this number of turns, however, one can now essentially Achieve finer corrections than was previously possible without an auxiliary kernel. The correction a secondary winding on the auxiliary core now means a change in the gear ratio of 0.20 / 0, based on the nominal current of 5 A, which is also sufficient in special cases should be.

The specified Vleßprinzip can be extended with respect to the improvement of defects in the Nleßkern. In the foregoing it was established that a relatively high induction is achieved in the auxiliary core even with a low nominal excitation and thus an improvement in the error profile can be achieved. This improvement is only effective in the initial area of the error curve, since the internal performance of the auxiliary core is only small due to its small cross-section, as required. It could easily be considered to subdivide the measuring core itself into two or more equal or unequal core parts and to provide each partial core with a special secondary winding in order to achieve the closest possible approximation to a practically straight running characteristic. Such an arrangement is shown in Fig. shown schematically. The actual measuring core now consists of the partial cores 7 and 8 with their secondary windings 9 and 10, which are excited by the common primary, # vicldung 11. Part 12 identifies the auxiliary core with its secondary winding 13. All three windings are connected in parallel and connected to terminals 1 and I of the load 14. The Suininetic current from the windings of the three cores is again 5 A. for the measuring core half 8 c also results in a secondary number of turns of 100 and for the auxiliary core 12 with a nominal current of 1 A a secondary number of turns of 200 turns.

A prerequisite are the cross-sections of the two measuring cores 7 and 8 different, but their secondary numbers of turns are the same. With a certain primary excitation, which occurs in all partial learning because of the single primary winding is the same, but the inductions in the partial nuclei are now different. Through this there are different working points on the magnetization curve for each core of iron and thus translation errors of various sizes. The dimensioning of the core cross-sections is expediently vorgonoinmen so that the core with the smaller cross-section already in the starting area of the error curve with as large an induction value as possible is working, while the second core with a larger cross-section is only full in the upper flow range takes effect. In order to achieve this goal, it may be useful to to produce the individual partial cores from core material of different permeability. It is also useful to make the auxiliary core from highly permeable to increase its effect To manufacture material. The visible success of the measuring arrangement according to the invention manifests itself in a stretched error curve, which is always desirable. Theoretically and in practice it can be further subdivided and specially designed the Teilm-eßkerne in the aforementioned sense a practically rectilinear error curve with a constant burden.

The dimensioning of the auxiliary core to reduce the overcurrent factor remains the same in all cases, so that the auxiliary kernel is parallel with the same success can be connected to a measuring core that is not or multiple subdivided.

This auxiliary core, which is also influenced by the primary current, can be used without restriction not only with rod current transformers, but also with all other winding current transformers be provided with success. It is irrelevant whether the original Converters with or without artificial switching are provided, because apart from the error correction In the case of small primary currents, the measuring arrangement with the auxiliary core is only activated in the overcurrent area of the converter fully effective.

Claims (4)

PATENT CLAIMS: 1. Current transformers, in particular bar current transformers, with the main and auxiliary core having the same primary electrical flow, the Load-feeding secondary windings are connected in parallel in the same direction, thereby characterized that the auxiliary core taking into account the core: material with respect to its effective cross-section and the number of turns of its secondary winding is that, in a manner known per se, already in the initial range of its rated current range there is a relatively high core induction, so that the main and auxiliary core act as a generator act, and that the auxiliary core is in saturation when the rated current range is exceeded arrives, so that from then on he acts as a consumer. 2. Current transformer according to claim 1, characterized in that the auxiliary core consists of highly permeable material. 3. Current transformer according to claim 1 and 2, characterized in that the measuring core itself is divided into two or more sub-cores, whose secondary windings are connected in parallel taking into account the iron cross-section like this. are dimensioned that they are 0.1 times up to 1.2 times the nominal current one after the other in the area of the highest possible induction reach. 4. Current transformer according to claim 1 to 3, characterized in that the individual part cores consist of core material of different permeability. Considered publications German Patent Nos. 526204, 544111, 623956, 720499, 868182; British Patent No. 418,933; U.S. Patent No. 2,476,787.